KR20100007207A - Electric multi cyclone scrubber - Google Patents

Abstract

PURPOSE: An electric multi-cyclone dust collector is provided to remove very fine gas and dust through the improved cyclone unit and discharge electrode unit. CONSTITUTION: An electric multi-cyclone dust collector comprises a dust collector body(400) in which gas flows in and out, a cyclone unit(200) which is accepted inside the dust collector body, collects dust from the inflow gas by centrifugal force, discharges the collected downward and the filtered gas upward, and a discharge electrode unit(300) which discharges high voltage between a cylindrical discharge tube and needle plates to collect minute dust from the gas discharged from the cyclone unit.

Description

Electric Multi Cyclone Scrubber

The present invention relates to an electric multi-cyclone dust collector, and more particularly, by improving the cyclone means and the discharge electrode means to further improve the efficiency of dust collection, such as gas and dust, and to improve the structure and size of the device, factories, buildings, houses Electric multi-cyclone dust collector that can be applied to various fields, such as automobiles.

In general, there are various devices for removing dust and gas contained in the exhaust gas emitted during combustion in incinerators and industrial boilers. Such a device for removing gas includes a wet scrubber, a semi-dry scrubber, an adsorption tower, a catalytic reactor, and the representative apparatus for removing dust is a gravity dust collector, an inertial dust collector, a centrifugal force dust collector, and a cleaning dust collector depending on the action force. Device, bag filter, and the like.

Recently, in order to further improve their efficiency, hybrid type dust collectors which combine two or more different functions have been developed. For example, a hybrid dust collector, that is, an electric cyclone dust collector, which combines an electric dust collecting function and a cyclone function using high voltage has been developed.

When the dust-collecting gas enters, the corona is generated from the discharge electrode connected to the high voltage power supply (about DC 60000V). As a result of the ionization, the particulates in the dust are charged and attracted to the dust-collecting electrode by the electric field and are captured. The electric cyclone method collects dust and gas by the centrifugal force of a cyclone.

Therefore, the electric cyclone dust collector as described above is known to further increase the dust collection efficiency by adding the electrostatic force of the electric dust collector to the dust collection force by the centrifugal force of the cyclone.

Referring to these existing devices with reference to Figures 1 and 2 the operational problems are described as follows.

First, in FIG. 1, in the conventional cyclone, when the exhaust gas containing the contaminant enters the cyclone 10 through the inlet 11, the particles move to the wall by centrifugal force and the contaminant outlet 12 by the downward airflow. Is collected through). However, at this time, small particulate contaminants and fine contaminants are not collected and are discharged to the air outlet 13 through the updraft discharged from the cyclone, so that the fundamental solution of the contaminants was not possible.

In order to improve this, in FIG. 2, an electric cyclone dust collector having a wire-type discharge electrode 14 is installed at the center of the cyclone 10 and the cyclone body is a dust collecting pole has been developed (see Korean Patent Publication No. 97-32981).

The cyclone dust collector adds electrostatic force to the centrifugal force of the cyclone. When the exhaust gas containing the contaminants enters the inlet 11, large particles are collected from the lower part by the downward air flow through the wall by the centrifugal force. And small particulate contaminants that do not move to the wall are space discharged between the wire-type discharge electrode 14 and the cyclone body by the high voltage supplied from the high voltage charging device 15, and by the electrons and ions generated at this time. The particles are charged.

The charged small particulate contaminants move to the wall by the electrostatic force and are collected together with the relatively large particle contaminants caused by the down stream, and are discharged through the contaminant outlet 12, but in the case of the electric cyclone, the flow rate is low. While the increase in dust collection efficiency is large, in the region where the cyclone inlet flow velocity is 15 m / s or more, the increase effect of the collection efficiency by the electrostatic force is insignificant.

Accordingly, since the fine particulate contaminants not collected by centrifugal force and electrostatic force are introduced into the inlet 11 and discharged directly to the air outlet 13 without filtration, the air pollution problem still remains.

As another example, Korean Patent Laid-Open Publication No. 2007-10623 discloses an electric cyclone and an electric cyclone scrub including the same.

As shown in FIG. 3, the conventional electric cyclone is fitted with a crown discharge electrode coupled to the outlet 130a of the cyclone 100 orthogonal to the exhaust gas inlet 110a instead of the conventional wire discharge electrode 14. 180) is applied. As shown in FIG. 4, the crown-shaped discharge electrode 180 has a flange portion 181a formed to be fitted to fit into the outlet 130a of the cyclone 100, and an insulator 181 of an insulator which is generally cylindrical. The connection inlet 182 is connected to the lower end of the insulator 181 and has a wedge-shaped discharge electrode 183 at the lower end thereof, and is connected to the high voltage charging device 150 thereon, and the insulator 181. And an electrode wire 184 embedded for electrical connection between the electrode 183 through the connection connector 182.

The advantage obtained by the crown discharge electrode 180 is that the applied voltage can be reduced by reducing the distance between the discharge electrode 183 and the dust collecting electrode by 1/2 compared to the wire discharge electrode 14, thereby reducing the cost of the high voltage charging device. In addition, since the collector electrode and the discharge electrode face each other, a uniform electric field is formed, and the tip of the discharge electrode has a sharp wedge shape, thereby providing a stable and efficient electrical structure.

However, these conventional electric cyclone dust collectors only have a one-step dust collection process, and thus filter out particles having a large particle size, but have a problem in that even fine gas and dust cannot be removed.

In addition, there is also a problem that the size of the device is very large in order to remove particulate contaminants with high efficiency, that is, to increase the efficiency of filtering dust through a plurality of steps.

The present invention is to overcome the above-mentioned conventional problems, and further improves the dust collection efficiency to remove even the minute gas and dust by improving the cyclone means and the discharge means, and also improve the structure, capacity and size of the device Therefore, an object of the present invention is to provide an electric multi-cyclone dust collector and its dust collecting method which can be applied to various fields such as factories, buildings, houses, automobiles, and the like.

In order to achieve the above object, an electric multi-cyclone dust collector according to the present invention includes a dust collector body for introducing and discharging gas; Cyclone means accommodated inside the dust collector main body, collecting dust by a centrifugal force generated by rotating the gas introduced into the dust collector main body and discharging the dust to a lower portion, and discharging the dust filtered gas to the upper portion; And discharge electrode means for discharging high voltage between the cylindrical discharge tube and the plurality of needle plates formed therein to collect fine dust of the gas discharged to the upper portion of the cyclone means.

The dust collector body is; An inlet formed at one side thereof to introduce exhaust gas from the outside; A duct extending from the inlet to the inside of the dust collector main body to guide the introduced exhaust gas into the main body; A dust collector formed at the lower portion of the duct to collect dust filtered by the cyclone means; And an outlet formed at an upper portion of the duct to discharge dust-filtered gas to the outside.

The cyclone means; A cyclone body having an inlet connected to the duct at an upper portion thereof and having a tapered dust outlet at a lower portion thereof; A wing formed near the inlet to guide the inlet gas to rotate inside the cyclone body; An air discharge pipe formed at an upper center of the inlet to discharge dust-filtered gas to an upper portion thereof; An insulating ring fitted to an outer circumferential surface of the cyclone body to connect the cyclone body to be insulated from the duct; And a backflow prevention part formed under the cyclone body to prevent the dust discharged to the dust discharge port from flowing back to the upper portion thereof.

The discharge means means; A discharge rod inserted into the discharge tube and an insulating ring interposed between the plurality of needle plates; The discharge tube is formed extending from the air discharge tube of the cyclone means toward the duct, and the plurality of needle plates are formed with a plurality of needles on the circumferential surface thereof, and a hole is formed in the center thereof, and the discharge rods are inserted at regular height intervals. .

The discharge means means; A high voltage discharge is generated between the plurality of needle plates electrically connected to the discharge rods and the inner surface of the discharge tube by applying different positive (+) or negative (−) voltages to the discharge tube and the discharge rod, respectively.

The discharge means means; And a first discharge electrode means formed in the duct and a second discharge electrode means formed on the duct, wherein the discharge tube and the needle plate of the second discharge electrode means have a diameter larger than that of the discharge tube and the needle plate of the first discharge electrode means. desirable.

At least one through hole is formed in the circumferential surface of the discharge tube of the second discharge electrode means, and the needle is not formed in the circumferential surface portion corresponding to the through hole in the needle plate of the second discharge electrode means.

The cyclone means and the discharge electrode means may be formed in at least one, and correspond to each other one-to-one may be arranged at regular intervals inside the main body of the dust collector.

According to the electric multi-cyclone dust collector according to the present invention, there is an effect of providing a high-efficiency multi-dust collector further improving the cyclone means and the discharge electrode means to further remove the fine gas and dust.

In addition, by improving the structure and size of the device, there is an effect that can easily apply and install the device of the appropriate capacity, structure and mass small size in various fields such as factories, buildings, houses, automobiles.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may properly define the concept of terms in order to best explain their invention in the best way possible. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, it is possible to replace them at the time of the present application It should be understood that there may be various equivalents and variations.

5 is a front view showing an electric multi-cyclone dust collector according to the present invention, Figure 6 is a side view of Figure 5, Figure 7 is a plan view of FIG.

As shown, the present invention is composed of a dust collector main body 400, the cyclone means 200 and the discharge electrode means (300).

The dust collector main body 400 introduces and discharges gas. To this end, the dust collector main body 400 includes an inlet 410, an outlet 420, a duct 430, and a lower dust collector 440.

Inlet 410 is formed on one side of the dust collector main body 400 to introduce the exhaust gas from the outside. The inlet 410 is preferably formed to protrude outward from the side of the main body 400 in a rectangular shape as shown.

In general, the exhaust gas is forced to the air inlet 410 through a separate blower fan (not shown).

The duct 430 extends from the inlet 410 into the dust collector main body 400 to guide the introduced exhaust gas into the main body 400. The duct 430 divides the main body 400 into an upper portion and a lower portion, and in particular, the inlet 410 may be formed in a wider structure and narrower inwardly.

Dust collector 440 is formed in the lower portion of the duct 430 to collect the dust filtered by the cyclone means (200). The dust collecting box 440 is preferably formed in a shape of narrowing down, and a door 441 for collecting dust collected at the lower end thereof and discharging it to the outside may be formed.

Discharge port 420 is formed in the upper duct 430 to discharge the filtered gas dust to the outside. The outlet 420 is formed at the top of the main body 400 and the cylindrical hole is bent upwardly connected to the outside.

In addition, the cyclone means 200 is accommodated in the dust collector main body 400, the dust is collected by the centrifugal force generated by rotating the gas introduced into the dust collector main body 400 to discharge the dust to the bottom, the dust to the top Drain the filtered gas.

In addition, the discharge electrode means 300 discharges a high voltage between the cylindrical discharge tube 340, 350, 360 and a plurality of needle plates (311, 321, 331) formed therein, the upper portion of the cyclone means (200) The fine dust of the gas discharged to the dust is collected.

The cyclone means 200 and the discharge electrode means 300 will be described in more detail with reference to FIG. 8 as follows.

8 is a cross-sectional view showing in detail the discharge means and the cyclone means according to the present invention.

As shown, the cyclone means 200 of the present invention, the cyclone body 210, the inlet port 220, the wing 230, the dust outlet 240, air discharge pipe 250, insulating ring 260, backflow The prevention part 270 is comprised.

The cyclone body 210 has an inlet 220 connected to the duct 430 at the upper portion thereof, and a tapered dust outlet 240 formed at the lower portion thereof. A dust collecting box 440 of the dust collector main body 400 is located below the dust outlet 240.

The wing 230 is formed in the vicinity of the inlet 220 to induce the gas to be rotated in the cyclone body 210. The wing 230 is formed such that the gas flows spirally into the inlet 220.

The air discharge pipe 250 is formed at the top of the center of the inlet 220 to discharge the dust-filtered gas to the upper portion thereof.

The insulating ring 260 is fitted to the outer circumferential surface of the cyclone body 210 to connect the cyclone body 210 to be insulated from the duct 430 of the dust collector main body 400.

The discharge means 300 of the present invention, the needle plate 311 (321) 331, the discharge rod 312 and the insulating ring 313 (323) 333, the discharge tube (340) (350) (360), It consists of a through hole 361.

The discharge rods 312 are inserted into the discharge tubes 340, 350 and 360.

A plurality of needle plates (311, 321, 331) are formed in the center hole is inserted into the discharge rod 312 at a predetermined height interval, a plurality of needles (314, 324, 334) on the circumferential surface Is formed.

The needles 314, 324, 334 mean sharp shapes, and may be expressed in other terms, such as a tip, a needle, a wedge, and all of these shapes.

Insulation rings 313, 323, and 333 are interposed between the plurality of needle plates 311, 321, and 331.

The discharge means 300 is applied to the discharge tube 340, 350, 360 and the discharge rod 312, respectively, by applying different positive (+) or negative (-) voltage to the discharge rod 312 and High pressure discharge is performed between the plurality of needle plates 311, 321, 331 and the inner surfaces of the discharge tubes 340, 350, 360 that are miraculously connected.

Preferably, the discharge means 300 includes a first discharge means 310 formed in the duct 430 and a second discharge means 320 formed on the duct 430.

In this case, the discharge tube 350 and the needle plate 321 of the second discharge electrode means 320 have a diameter larger than that of the discharge tube 340 and the needle plate 311 of the first discharge electrode means 310.

9 is a cross-sectional plan view showing in detail the arrangement state according to an embodiment of the electrode unit according to the invention, Figure 10 is a side cross-sectional view of Figure 9, Figure 11 is a shape of the needle plate applied to the embodiment of Figure 9 It is the top view shown.

As shown, the cyclone means 200 and the discharge electrode means 300 of the present invention is formed with at least one, each one to one corresponding to each other are arranged at regular intervals inside the dust collector main body 400 It is preferable.

Here, the discharge tube 350 of the second discharge electrode means 320 is supported on the dust collector main body 400, the discharge rod 312 including the needle plate 321 is a plurality of horizontal rods formed insulated from the main body 400 It is preferable to be provided at 401.

Therefore, a positive voltage is applied to the discharge rod 312 and an over-minus (−) voltage is applied to the discharge tube 350 to generate a high pressure discharge therebetween, and the fine dust contained in the gas discharge tube 350. ) Is charged on the surface.

At this time, one embodiment of a plurality of needle plate (311, 321) is applied, as shown in Figure 11, a hole is formed in the center is fitted to the discharge rod 312 at a predetermined height interval, the circumferential surface A plurality of needles 314 and 324 have a shape formed. In addition, an insulating ring 323 is sandwiched between the needle plates 311 and 321 and stacked at a predetermined interval.

12 is a cross-sectional plan view showing in detail the arrangement state according to another embodiment of the discharge electrode means according to the invention, Figure 13 is a side cross-sectional view of Figure 12, Figure 14 is a shape of the needle plate applied to another embodiment of Figure 12 It is the top view shown.

As shown, the discharge tube 360 according to another embodiment of the present invention, at least one through hole 361 is formed in the circumferential surface, the needle plate 331 is a portion of the circumferential surface corresponding to the through hole 361 The needle 334 is not formed.

The discharge tube 360 according to another embodiment of the present invention configured as described above is arranged at a predetermined interval inside the dust collector main body 400 together with the discharge tube 350 of the second discharge electrode means 320.

Therefore, more high-pressure discharges are generated at the upper part of the dust collector main body 400 to further improve the dust collecting efficiency of the fine dust.

If described in detail through the accompanying drawings the operation of the present invention configured as described above are as follows.

First, the exhaust gas is introduced from the outside through the inlet 410 formed on one side of the dust collector main body 400.

The inlet 410 is formed to protrude outward from the side of the main body 400 in a rectangular shape as shown in Figs. 5 and 6, the exhaust gas is the inlet 410 through a separate blowing fan (not shown) Pressurizing to the side is forcibly blown.

Thereafter, the duct 430 guides the discharge gas introduced from the inlet 410 into the main body 400.

At this time, the cyclone means 200 collects the dust by the centrifugal force generated by rotating the gas introduced into the duct 430 of the dust collector main body 400 to discharge the dust to the bottom, and discharge the dust filtered gas to the top.

That is, as shown in FIG. 8, the gas introduced into the duct 130 is introduced into the cyclone body 210 through the inlet 220 of the upper portion of the cyclone body 210. In this case, the wing 230 formed near the inlet 220 induces the gas to be rotated in the cyclone body 120.

Therefore, the dust collected by the centrifugal force is discharged to the outside through the tapered dust outlet 240 in the lower portion of the cyclone body (210). The dust discharged from the dust is collected in the dust collecting box 440 formed at the bottom thereof.

On the other hand, the dust is filtered gas by the centrifugal force is discharged to the upper portion along the air discharge pipe 250 formed to the upper center of the inlet (220).

As described above, the dust is filtered using the cyclone means 200, and the fine dust of the gas discharged to the upper portion of the cyclone means 200 is collected using the discharge electrode means 300.

That is, the discharge electrode means 300 discharges a high voltage between the cylindrical discharge tubes 340, 350, 360 and the plurality of needle plates 311, 321, 331 formed therein, and thus the upper portion of the cyclone means 200. The fine dust of the gas discharged to the dust is collected.

Such a discharge action will be described in more detail with reference to FIG. 8.

The gas filtered by the cyclone means 200 is moved to the upper portion of the discharge tube 340 along the air discharge pipe 250. At this time, a discharge rod 312 is inserted into the discharge tube 340. In addition, a plurality of needle plates 311 and 321 having a plurality of needles 314 and 324 formed on the circumferential surface thereof have a hole formed in the center thereof, and each of the insulating rings 313 and 323 in the discharge rod 312. They are separated by) and inserted at regular height intervals.

Accordingly, the plurality of needle plates 311 and 321 electrically connected to the discharge rods 312 by applying different positive (+) or negative (−) voltages to the discharge tube 340 and the discharge rods 312, respectively. ) And a high pressure discharge is made between the inner surface of the discharge tube 340.

Here, preferably, the discharge means 300 is composed of a first discharge means 310 formed in the duct 430, the second discharge means 320 formed on the duct 430.

Therefore, the gas passing through the discharge tube 340 of the first discharge electrode means 310 is formed by the first high pressure discharge between the plurality of needles 314 and the discharge tube 340 on the circumferential surfaces of the plurality of first needle plates 311. Fine gas is filtered out.

Thereafter, the gas passing through the other discharge tube 350 of the second discharge electrode means 320 is discharged by the secondary high pressure discharge between the needles 324 and the discharge tube 350 on the circumferential surfaces of the plurality of second needle plates 321. Fine gas is further filtered.

Therefore, the cyclone means and the discharge means can be improved to remove even very fine gas and dust. In addition, by improving the structure and size of the device it is possible to easily apply and install the device of the appropriate capacity, structure and mass small size in various fields, such as factories, buildings, houses, automobiles.

That is, by adjusting the arrangement and the number of the cyclone means 200 and the discharge electrode means 300 of the present invention as shown in Figure 11, it is possible to conveniently adjust the size of the device to an appropriate capacity.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the present invention should be understood only by the claims set forth below, and all equivalent or equivalent modifications thereof will belong to the scope of the present invention.

1 and 2 are cross-sectional views showing a conventional cyclone dust collector.

3 and 4 are cross-sectional views showing a conventional electric cyclone dust collector.

5 is a front view showing the electric multi-cyclone dust collector according to the present invention.

6 is a side view of FIG. 5;

7 is a plan view of FIG.

8 is a cross-sectional view showing in detail the discharge means and the cyclone means according to the present invention.

Figure 9 is a cross-sectional view showing in detail the arrangement state according to an embodiment of the electrode unit according to the invention.

10 is a side cross-sectional view of FIG. 9;

11 is a plan view showing the shape of a needle plate applied to the embodiment of FIG.

12 is a cross-sectional plan view showing in detail the arrangement of the discharge electrode means according to another embodiment of the present invention.

13 is a side cross-sectional view of FIG.

14 is a plan view showing the shape of a needle plate applied to another embodiment of FIG.

<Explanation of symbols for the main parts of the drawings>

200: cyclone means 210: cyclone body

220: inlet 230: wing

240: dust discharge port 250: air discharge pipe

260: insulation ring 270: backflow prevention

300: discharge electrode means 310: first discharge electrode means

320: second discharge electrode means 311: first needle plate

312: discharge rods 321, 331: second needle plate

313, 323, 333: Insulation ring 314, 324, 334: Needle

340, 350, 360: discharge tube 361: through hole

400: dust collector body 410: inlet

420: outlet 430: duct

440: lower dust collector

Claims (8)

A dust collector body for introducing and discharging gas; Cyclone means accommodated inside the dust collector main body, collecting dust by a centrifugal force generated by rotating the gas introduced into the dust collector main body and discharging the dust to a lower portion, and discharging the dust filtered gas to the upper portion; And An electric multi-cyclone dust collector comprising a discharge electrode means for collecting a high dust discharge between the cylindrical discharge tube and a plurality of needle plates formed therein to collect the fine dust of the gas discharged above the cyclone means. The method of claim 1, The dust collector body is; An inlet formed at one side thereof to introduce exhaust gas from the outside; A duct extending from the inlet to the inside of the dust collector main body to guide the introduced exhaust gas into the main body; A dust collector formed at the lower portion of the duct to collect dust filtered by the cyclone means; And The multi-cyclone dust collector is formed on the duct and comprises an outlet for discharging the dust is filtered gas to the outside. The method of claim 1, The cyclone means; A cyclone body having an inlet connected to the duct at an upper portion thereof and having a tapered dust outlet at a lower portion thereof; A wing formed near the inlet to guide the inlet gas to rotate inside the cyclone body; An air discharge pipe formed at an upper center of the inlet to discharge dust-filtered gas to an upper portion thereof; An insulating ring fitted to an outer circumferential surface of the cyclone body to connect the cyclone body to be insulated from the duct; And And a backflow prevention part formed under the cyclone body to prevent backflow of dust discharged to the dust discharge port to an upper portion thereof. The method of claim 1, The discharge means means; A discharge rod inserted into the discharge tube and an insulating ring interposed between the plurality of needle plates; The discharge tube is formed extending from the air discharge tube of the cyclone means toward the duct, The plurality of needle plates, a plurality of needles are formed on the circumferential surface and a hole is formed in the center of the electric multi-cyclone dust collector, characterized in that fitted to the discharge rod at a predetermined height interval. The method of claim 4, wherein The discharge means means; A high voltage discharge is generated between the plurality of needle plates electrically connected to the discharge rod and the inner surface of the discharge tube by applying different positive (+) or negative (−) voltages to the discharge tube and the discharge rod, respectively. Multi cyclone dust collector. The method of claim 4, wherein The discharge means means; A first discharge electrode means formed in the duct and a second discharge electrode means formed on the duct, The discharge tube and the needle plate of the second discharge means means has a larger diameter than the discharge tube and the needle plate of the first discharge means means. The method of claim 6, The discharge tube of the second discharge electrode means, At least one through-hole is formed in the circumferential surface, the needle plate of the second discharge electrode means is characterized in that the needle is not formed in the circumferential surface portion corresponding to the through-hole electric multi-cyclone dust collector. The method of claim 1, The cyclone means and the discharge electrode means, An electric multi-cyclone dust collector is formed of at least one, each corresponding to one to one each other and arranged at a predetermined interval inside the main body of the dust collector.

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